Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Query: UMLS:C1389183 (
autodigestion
)
317
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Acute pancreatitis (AP) is believed to result from intraparenchymal activation of trypsin and other digestive enzymes within the pancreas followed by
autodigestion
of the gland. Gabexate mesilate (FOY), a synthetic guanidino acid ester exhibiting potent and versatile inhibitory actions on a number of proteinases (e.g., trypsin,
kallikrein
, C1-r, C1 esterase, plasmin, thrombin, phospholipase A2), was examined for its ability to protect the rat pancreas against development of AP induced by pharmacological doses of ceruletide (CRT). Rats were i.v. infused for 6 h with either CRT (5 micrograms/kg/h) or CRT + FOY (50 mg/kg/h). In FOY-treated rats the serum amylase and trypsinogen concentrations were reduced by 60 and 80%, respectively, compared to rats infused with CRT alone. Histologically, the extent of acinar cell vacuolization in the pancreas was significantly reduced and interstitial edema, although not assessed by quantitative morphometric techniques, appeared to be qualitatively lessened in the FOY-treated rats. The ability of FOY to inhibit significantly AP produced by supramaximal doses of CRT, coupled with its inhibitory properties on components of the coagulation and complement cascades, stress the importance of continued research on this compound as a potential therapeutic agent for treatment of AP and its systemic sequelae.
...
PMID:Gabexate mesilate (FOY) protects against ceruletide-induced acute pancreatitis in the rat. 244 41
The concentration of bradykinin in human plasma depends on its relative rates of formation and destruction. Bradykinin is destroyed by two enzymes: a plasma carboxypeptidase (anaphylatoxin inactivator) removes the COOH-terminal arginine to yield an inactive octapeptide, and a dipeptidase (identical to the angiotensin-converting enzyme) removes the COOH-terminal Phe-Arg to yield a fragment of seven amino acids that is further fragmented to an end product of five amino acids. Formation of bradykinin is initiated on binding of Hageman factor (HF) to certain negatively charged surfaces on which it autoactivates by an
autodigestion
mechanism. Initiation appears to depend on a trace of intrinsic activity present in HF that is at most 1/4000 that of activated HF (HFa); alternatively traces of circulating HFa could subserve the same function. HFa then converts coagulation factor XI to activated factor XI (XIa) and prekallikrein to
kallikrein
. Kallikrein then digests high-molecular-weight kininogen (HMW-kininogen) to form bradykinin. Prekallikrein and factor XI circulate bound to HMW-kininogen and surface binding of these complexes is mediated via this kininogen. In the absence of HMW-kininogen, activation of prekallikrein and factor XI is much diminished; thus HMW-kininogen has a cofactor function in kinin formation and coagulation. Once a trace of
kallikrein
is generated, a positive feedback reaction occurs in which
kallikrein
rapidly activates HF. This is much faster than the HF autoactivation rate; thus most HFa is formed by a
kallikrein
-dependent mechanism. HMW-kininogen is also therefore a cofactor for HF activation, but its effect on HF activation is indirect because it occurs via
kallikrein
formation. HFa can be further digested by
kallikrein
to form an active fragment (HFf), which is not surface bound and acts in the fluid phase. The activity of HFf on factor XI is minimal, but it is a potent prekallikrein activator and can therefore perpetuate fluid phase bradykinin formation until it is inactivated by the C1 inhibitor. In the absence of C1 inhibitor (hereditary angioedema) HFf may also interact with C1 and activate it enzymatically. The resultant augmented bradykinin formation and complement activation may account for the pathogenesis of the swelling characteristic of hereditary angioedema and the serologic changes observed during acute attacks.
...
PMID:Hageman factor-dependent pathways: mechanism of initiation and bradykinin formation. 655 44
We have compared the cleavage of purified human Hageman factor (HF) by an activated form of human Hageman factor (HFa) (
autodigestion
) and by
kallikrein
. In each case, an initial cleavage is seen which produces HFa with Mr = 80,000 consisting of a heavy chain of Mr = 52,000 disulfide-linked to a light chain of Mr = 28,000. As
autodigestion
proceeds, HFa is shown to be further digested to yield a major active product at a molecular weight of 40,000 as well as Hageman factor fragment (HFf), which appear as two closely related molecular species of Mr = 28,000 and 30,000. A minor active product of Mr = 70,000 is also seen. Upon reduction of each of the active forms, a chain with Mr = 28,000 is released which contains the active site. HF digestion by
kallikrein
results in rapid formation of HFa, followed by HFa digestion to HFf and degradation of the heavy chain region to an inactive fragment at 40,000 daltons, which is then degraded to an end product of Mr = 36,000. Production of the active species with Mr = 40,000 and 70,000 is greatly diminished when
kallikrein
is the HF activator, and these active forms are shown to be formed primarily by
autodigestion
. The time course of HFa and HFf formation indicates that the rate of activation of Hageman factor by
kallikrein
is much faster than the rate of autoactivation; the addition of high molecular weight kininogen increases the rate of HFa and HFf formation as well as the extent of HG digestion. These data indicate that HFa is the active intermediate from which other active species are derived. The patterns of HF and HFa digestion by HFa and
kallikrein
are distinct; a model for HF digestion is presented.
...
PMID:The cleavage and formation of activated human Hageman factor by autodigestion and by kallikrein. 691 37
